Expansion valve

ABSTRACT

An expansion valve operable by a stepper motor, the expansion valve including a housing; a hollow shaft arranged in the housing; a valve base that supports the hollow shaft and closes the housing; a rotor that is drivable by a stator of the stepper motor; a center spool arranged within the hollow shaft and drivable by the rotor so that a rotation of the center spool is transferrable by a threaded connection into an axial movement of the center spool that opens or closes the expansion valve; and a spiral body that includes a thread turn and that is arranged about an enveloping surface of the hollow shaft and that is drivable by the rotor, wherein a stop body is arranged at the hollow shaft and movable in the thread turn of the spiral body.

RELATED APPLICATIONS

This application claims priority from and incorporates by referenceGerman patent applications

DE 10 2019 132 976.0 filed on Dec. 4, 2019; andDE 10 2020 124 871.7 filed on Sep. 24, 2020.

FIELD OF THE INVENTION

The invention relates to an expansion valve.

BACKGROUND OF THE INVENTION

Expansion valves also designated as throttle valves are devices ingeneral that reduce a pressure of a fluid by running the fluid through alocally constricted flow cross section to cause a volume increase orexpansion. Typically, expansion valves include a mechanism thattransposes a rotating movement into an axial movement for opening andclosing the expansion valve. Axial movements for opening and closing theexpansion valve require a delimitation or a defining of two end pointsusing a stop structure.

Expansion valves of this type are well known in the art. JP 3328530 B2discloses a stopper structure for a powered valve. In this valve apercentage of opening of a valve seat in a main valve body is controlledby rotating a rotor of a motor by running electricity through a statorof the motor. The stator is attached at the outer circumference of thehousing. Threading an inner thread in an outer thread transposes therotation of the rotor into a linear movement.

The stopper structure that is configured to define the two end pointswhen opening and closing the expansion valve includes a stopper, anengagement element and an annular support pin.

The stopper is vertically arranged at a location that is distal from thecenter at a backside of a cover at an upper end portion of the housing.

The engagement component includes a long narrow shaft which extends atan opposite side of a valve shaft that is integrally configured with therotor. Thus, the shaft is inserted into a support path with a helicalcenter portion and protruding portions at a top end and a bottom end,wherein the upper protruding portion is arranged at an upper end portionof the shaft and wherein the upper protruding portion is bent upward.

The stopper structure additionally includes an annular support pin thatincludes an annular portion that is wound approximately once about thehelical center portion and that includes an arm that extends in an outercircumferential direction below the annular portion so that a contactwith the stopper is caused that is arranged in a helical groove of thesupport path.

Thus, an upper end portion of the support pin contacts the protrudingportion of the support path when the annular support pin moves along thehelical groove of the support path. Additionally, the arm of the supportpin contacts the engagement portion that is configured at the lowerprotruding portion when the support pin moves downward along the helicalgroove of the support path.

Overall, the configuration of the prior art expansion valve describedsupra is very complex. This level of complexity not the only problem.Rather, all prior art expansion valves have the disadvantage that theyrequire a complicated and complex configuration to perform theirfunction. This complicated configuration also has the inevitable effectthat a simple replacement of the expansion valve or parts thereof is notpossible.

Additionally, the prior expansion valves also have a problem in thatthey are subjected to a high level of wear. As a consequence, the priorart expansion valves have to be replaced rather often and typically intheir entirety.

In addition to a simpler configuration which facilitates a simplerreplacement of entire expansion valves as well as components thereof awear reduced expansion valve is also highly desirable.

It is another disadvantage of the prior art expansion valves that theirfabrication is complex and therefore expensive.

BRIEF SUMMARY OF THE INVENTION

Thus, it is an object of the invention to provide an expansion valvethat overcomes the problems and disadvantages of the prior art describedsupra. In particular it is an object of the instant invention to providean expansion valve that has little wear and that is configured compact.It is another object of the invention to provide an expansion valve thatis particularly easily replaceable. It is another object of the instantinvention to provide an expansion valve that facilitates pressurebalancing between different spaces within the expansion valve in a lowwear compact configuration that also facilitates a simple replacement.

It is another object of the invention to provide a method for producingan expansion valve that is less complex than the prior art methods.

The expansion valve according to the invention is operable by a steppermotor and includes the following: a housing; a hollow shaft that isarranged in the housing; a valve base element that supports the hollowshaft and that closes the housing; a rotor that is drivable by a stator;a center spool that is arranged within the hollow shaft and drivable bythe rotor so that a rotation of the spool is transferrable through athreaded connection into an axial movement for opening and closing theexpansion valve; and a spiral body that includes a thread turn and thatis arranged on an enveloping surface of the hollow shaft and drivable bythe rotor, wherein a stop element is arranged at the hollow shaft andmovable in the thread turn of the spiral body and predetermines an upperend position and a lower end position of the center spool by formingpart of a spool stopper structure.

The center spool is configured in particular as a threaded spool whichconverts a rotation of the rotor into a linear movement in cooperationwith other elements, in this case an inner thread of the hollow shaft.

Thus, the center spool is connected with the rotor. The spiral body is aseparate element and not part of the hollow shaft. Thus, the spiral bodyis also connected with the rotor so that the rotor can drive the spiralbody.

The stop element is arranged in particular on the enveloping surface ofthe hollow shaft and contacts a first upper stop element when the centerspool is in its lower end position and contacts a second lower stopelement when the center spool is in its upper end position. The stopelement can be a rod-shaped element. A pitch of the spiral body and ofthe spool determines whether the upper end position or the lower endposition of the spool is predetermined.

Since the spiral body that includes the thread turn is separatelydrivable by the rotor and the stop element is arranged so that it ismovable in the thread turn a particularly compact configuration of theexpansion valve can be provided.

According to an advantageous embodiment of the invention the hollowshaft includes a longitudinal groove at the enveloping surface whereinthe stop element is configured as a sliding ring that is secured againstrotation in the thread turn of the spiral body by the longitudinalgroove and movable in the axial direction.

Depending on the direction of rotation the sliding ring is moved axiallyup and down along the hollow shaft within the longitudinal groove.

Since the sliding ring is movable up and down within the longitudinalgroove the overall size of the expansion valve can be reduced so thatthe expansion valve can be configured even more compact. Thelongitudinal groove and the sliding ring provide a simple configurationwith a high level of functional reliability.

Furthermore, the packet including the spiral body and the siding ring issecured at the enveloping surface of the hollow shaft by securing thesliding ring in the longitudinal groove. Thus, the support groove incooperation with the sliding ring provides loss safety.

According to an advantageous embodiment of the invention, the spoolstopper structure is provided by a cooperation of the spiral body andthe sliding ring.

According to an advantageous embodiment of the invention, the slidingring includes a radially inward extending protrusion that is configuredto run in the longitudinal groove and to act as a rotation safety.

This radially inward extending protrusion provides a simple option tosecure the sliding ring against rotation so that the sliding ring isaxially movable in the longitudinal groove in a reliable manner.

According to an advantageous embodiment of the invention, the spiralbody includes a first stop element that extends in the axial directionof the spiral body and a second stop element that extends in the axialdirection of the spiral body.

The axial direction of the spiral body is a direction that extends alongan axis about which the spiral body is wound. In installed conditionthis axis is at least essentially concentric to a rotation axis of thehollow shaft and a rotation axis of the spool. In particular the firststop element extends in a direction opposite to an extension directionof a second stop element of the spiral body. Both directions, however,are axial directions of the spiral body.

According to an advantageous embodiment of the invention the lower endposition of the spool is defined by the first stop element contactingwith the stop body and the upper end position of the spool is defined bythe second stop element contacting with the stop body plus a maximumtorsion angle of the spiral body.

When the spiral body is a rigid body without torsion elasticity amaximum torsion angle of the spiral body is zero so that the upper endposition of the spool is defined when the second stop element contactsthe stop body.

However, when the spiral body is configured torsion elastic the spool ismovable within limits of the elasticity of the spiral body also afterthe second stop element contacts the stop body. When the second stopelement contacts with the stop body the upward movement of the spool isdampened. Alternatively the upper end position of the center spool canalso be defined by the first stop element contacting with the stop body,wherein the lower position of the spool is defined when the secondcontact element contacts with the stop body plus the maximum torsionangle of the spiral body.

It is a function of a pitch of the spiral body and the pitch of thecenter spool whether the upper end position or the lower end position ofthe center spool is defined. In particular this is a function of thethread being a right turning thread or a left turning thread. Only whenthe pitch of the center spool differs from the pitch of the spiral bodythe first stop element defines the upper spool position. When the centerspool and the spiral body have the same pitch direction a travel of thecenter spool and of the sliding ring is opposed. Accordingly, the firststop element also defines the lower spool position.

According to an advantageous embodiment of the invention, the slidingring is configured as a cylindrical coil and includes an upper end and alower end that is arranged opposite to the upper end, wherein the upperend comes in contact with the first stop element, and the lower endcomes in contact with the second stop element.

Since the sliding ring is configured as a cylindrical spiral the slidingring is retained particularly well within the spiral body. Furthermore,it is possible to configure the sliding ring, this means the cylindricalspiral so that the upper end and the lower end overlap. This means thatthe cylindrical spiral is provided over an angular range that exceeds360 degrees wherein the overlap is the angular range over 360 degrees.This overlap of the ends and the number of windings of the spiral bodycan predetermine and/or limit a maximum number of possible rotations.

According to an advantageous embodiment of the invention, the spiralbody is connected by the first stop element with an adapter element sothat the spiral body is co-rotated when the rotor is rotated, whereinthe adapter element connects the rotor with the spool in order to rotatethe spool with the rotor.

Thus, the adapter element is connected in a force transferring mannerwith the spool e.g. by a press fit, a weld, or form locking. The adapterelement can be connected with the rotor in a forming locking manner. Forthis purpose, the adapter element does not have a rotation symmetriccross section. For example, the outer shape of the adapter element canhave a triangular cross section viewed along the rotation axis R or itcan be rectangular or polygonal or e.g. also with teeth. The inner shapeof the rotor may then have a cross section that is complementary to theshape of the adapter element.

This means that the first stop element of the spiral body performs adouble function in addition to the function as a stop element it alsofunctions as a driver element, this means connector element to the rotoror as the adapter.

Since the rotation of the rotor is not directly but indirectlytransferred by the adapter it is also possible to produce differentexpansion valves, e.g. with different rotors with as many identicalcomponents as possible.

According to an advantageous embodiment of the invention the spiral bodyis a torsion spring that is configured as a coil spring made from steel.

The steel has sufficient elasticity to be formed into a spiral body.Thus production of the spiral body is facilitated.

According to an advantageous embodiment of the invention the hollowshaft is made from a synthetic material, advantageously polyphenylenesulfide (PPS) or poly ether ketone (PEEK) or brass or bronze.

When using a synthetic material, the expansion valve is weight reducedcompared to using a metal material. Additionally, the syntheticmaterials (PPS) and (PEEK) are high performance materials so that theyare continuously useable in a high temperature range up to 240° C. andfor short time periods up to 300° C. Consequently, the expansion valvecan also be used under extreme conditions without any concern of theexpansion valve failing.

According to an advantageous embodiment of the invention the expansionvalve furthermore includes a sleeve element that includes a receivingportion and a valve needle, wherein the receiving portion receives aplunger shaped end portion of the center spool, a compression spring anda force transmission element in their entirety.

Since the expansion valve is configured with a sleeve element of thistype that performs the function of the valve needle and that provides areceiving portion on the other hand side a particularly compactconfiguration of the expansion valve can be achieved. In spite of thecompact configuration all functions of the expansion valve can beperformed reliably.

According to an advantageous embodiment of the invention the forcetransmission element is configured and arranged so that a contact withthe center spool transfers axial forces from the center spool throughthe compression spring to the sleeve element, wherein a cross section ofthe force transmission element is configured mushroom shaped so thattorques are transmitted from the center spool to the force transmissionelement not at all or only up to a limited amount.

Since the force transmission element is configured mushroom shaped acontact point, this means the force transmission point to the centerspool is small. Torques are only transferred by friction up to a limitedamount to the force transmission element at the force transmissionpoint. Overall, this leads to an expansion valve with particularly lowwear.

According to an advantageous embodiment of the invention the housing anda side of the valve base element that is oriented towards the housingdefine an interior housing cavity wherein a hollow shaft interior cavityis formed within the hollow shaft wherein a fluid inlet cavity isarranged adjacent to a side of the valve base element that is orientedaway from the housing in a condition where the expansion valve isinstalled in a valve installation space, wherein a first pressurebalancing channel is arranged that balances a pressure between the fluidinlet cavity and the housing interior, wherein the first pressurebalancing channel includes a first channel portion and a second channelportion and wherein the second channel portion is formed by thelongitudinal groove.

Also this facilitates a particularly compact configuration of theexpansion valve. In particular components can be eliminated in thatexisting components are assigned a second function.

Thus, the longitudinal groove does not only have the function of guidingthe slip ring but also performs the function of a pressure balancingchannel. Thus, the longitudinal groove performs a double function sinceit supports the slip ring and additionally forms a portion of the secondpressure balancing channel.

According to an advantageous embodiment of the invention a secondpressure balancing channel provides pressure balancing between thehollow shaft interior and the housing interior in a portion where thelongitudinal groove and the hollow shaft interior cavity has a maximumradial extension.

This facilitates reliable pressure compensation between the hollow shaftinterior cavity and the housing interior cavity.

Another solution according to the invention relates to an expansionvalve that is operable by a stepper motor, the expansion valvecomprising: a housing; a hollow shaft that is arranged in the housing; avalve base element that supports the hollow shaft and closes thehousing; a rotor that is drivable by a stator; a center spool that isarranged within the hollow shaft and drivable by the rotor so that arotating movement of the spool is transferrable through a threadedconnection into an axial movement for opening and closing the expansionvalve; an adapter element that transfers a torque from the rotor to thespool and is arranged between the rotor and the spool; and a spiral bodythat is arranged on a jacket side of the hollow shaft and rotatable bythe adapter element, wherein the spiral body includes an axiallyextending first stop element that is arranged in an off center openingof the adapter element.

Since the adapter element is arranged between the spool and the rotorthe configuration of the expansion valve is overall more universal. Thismeans e.g. that different rotors can be used. Furthermore, the adapterperforms a second function since it drives the spiral body to rotate.

The adapter element includes central rotation axis R wherein theoff-center opening is arranged off center from the center rotation axisR.

According to an advantageous embodiment of the invention the adapterelement includes a plate shaped base portion and a receiving portion forthe center spool that centrally extends from the plate shaped baseportion in an axial direction.

The axially extending receiving portion has the advantage that atolerance for the bore hole can be expanded since a long support reducesan ability of the components to tilt relative to each other.

The connection between the spool and the adapter element is performede.g. after alignment at a top side of the spool. The connection can beprovided by laser welding wherein several weld points are advantageouslyprovided.

Since only the base portion is configured plate shaped weight can besaved compared to a completely plate shaped adapter element.

According to an advantageous embodiment of the invention a central passthrough opening along the rotation axis R of the adapter element isconfigured to receive an upper portion of the spool.

The central pass through opening extends along the rotation axis R ofthe adapter element, a cross section of the central pass through openingis advantageously circular in order to facilitate a particularly simplealignment of the spool stopper structure or of the upper stop.

However, the central pass through opening does not have to be a circularopening. The cross section of the central pass through opening does nothave to be rotation symmetrical. For example, the pass-through openingcan be triangular, rectangular or polygonal or configured with ateething configured along the rotation axis R.

This facilitates a particularly simple force transmission from theadapter element to the spool, more precisely to the upper portion of thespool. The upper portion of the spool has a cross section that iscomplementary to the shape of the central pass through opening.

According to an advantageous embodiment of the invention, the outershape of the adapter element is not rotation symmetrical with respect tothe rotation axis R.

According to an advantageous embodiment of the invention the off-centeropening is arranged in the plate shaped base portion wherein the plateshaped base portion advantageously includes additional off-centeropenings.

Since the off-center opening is arranged in the plate shaped baseportion of the adapter element it can be arranged far away from acenter, i.e. the rotation axis of the adapter element. A larger distancebetween the off center opening and the rotation axis R facilitatesbetter force transmission through a longer lever arm.

Arranging additional off-center openings facilitates integratingadditional functions into the adapter element.

According to an advantageous embodiment of the invention the off-centeropenings are configured as slotted holes.

Slotted holes have the advantage of being simpler to fabricate sincethey can be introduced into the adapter element or into the plate shapedbase portion of the adapter element from a side, this means at a rightangle to the rotation axis.

According to an advantageous embodiment of the invention at least one ofthe additional off-center openings is arranged so that it balances apressure in the housing interior space above the adapter element andbelow the adapter element.

Thus, the adapter element additionally performs a pressure balancingfunction. One more time a component is configured so that it can performseveral functions which further reduces the component count.

According to an advantageous embodiment of the invention the spiral bodyincludes a thread turn, wherein the hollow shaft includes a longitudinalgroove at the enveloping surface and wherein a sliding ring is arrangedin the thread turn of the spiral body axially movable and torque proofin the longitudinal groove.

Since the sliding ring is movable up and down within the longitudinalgroove an installation size of the expansion valve can be reducedoverall so that the expansion valve can be configured more compact. Thelongitudinal groove and the sliding ring provide a simple configurationwith a high level of functional reliability.

Since the sliding ring is secured in the longitudinal groove the packetincluding the spiral body and the sliding ring is also secured at theenveloping surface of the hollow shaft. Thus, the support groovetogether with the sliding ring also functions as a loss safety.

According to an advantageous embodiment of the invention the cooperationof the spiral body and of the sliding ring forms a spool stopperstructure that determines an upper end position and a lower end positionof the center spool.

According to an advantageous embodiment of the invention the spiral bodyincludes a second stop element that extends in an axial directionopposite to the first stop element.

According to an advantageous embodiment of the invention the slidingring is configured as a cylindrical spiral that includes an upper endand a lower end.

When the sliding ring is configured as a cylindrical spiral aparticularly good retention of the sliding ring within the spiral bodycan be achieved. Furthermore, it is possible to configure the slidingring this means the cylindrical spiral so that the upper end and thelower end of the sliding ring overlap. Thus, the cylindrical spiralextends beyond a full circle, this means beyond 360°. Thus, the overlapis the portion that extends beyond the full circle. This overlap of theends and the number of windings of the spiral body can predetermineand/or limit the maximum number of revolutions.

According to an advantageous embodiment of the invention a radiallyinward extending protrusion is configured at one of the two ends.

This radially inward extending protrusion offers a simple option tosecure the sliding ring against rotation so that the sliding ring isreliably movable in the axial direction in the longitudinal groove.

According to an advantageous embodiment of the invention the radiallyinward extending protrusion of the sliding ring is configured to extendin the longitudinal groove of the hollow shaft so that it functions as arotation safety.

According to an advantageous embodiment of the invention a lower endposition of the spool is defined by a contact of the first stop elementat the upper end and the upper end position of the spool is defined whenthe second stop element contacts the lower end plus a maximum torsionangle of the spiral body.

When the spiral body is a body that cannot be preloaded in the rotationdirection, thus the spiral body is rigid and not torsion elastic themaximum torsion angle of the spiral body is zero. Then the upper endposition of the spool is predetermined when the second stop elementcontacts the stop body. However, when the spiral body is configuredtorsion elastic, thus pre-loadable in the rotation direction, the spoolis still movable even after the contact of the second stop element atthe stop body since the spool preloads the spiral body.

This means that the rotation of the spool is dampened in upwarddirection when the second stop element contacts the stop body.

As an alternative thereto, the upper end position of the spool can alsobe predetermined when the first stop element contacts the stop body,wherein the lower end position of the spool is defined by the contact ofthe second stop element at the stop body plus the maximum torsion angleof the spiral body.

It is determined by the pitch of the spiral body whether the upper endposition of the spool or the lower end position of the spool is defined.This depends in particular from the thread being a right-hand thread ora left-hand thread. Only when the thread pitch of the spool differs fromthe thread pitch of the spiral body, the first stop element also definesthe upper spool position. When the spool and the spiral body have thesame thread pitch direction a travel path of the spool and of thesliding ring is opposite. Accordingly, the first stop element then alsodetermines the lower spool position.

According to an advantageous embodiment of the invention the spiral bodyis a torsion spring that is configured as a steel coil spring.

Thus, the spiral body can be fabricated in a particularly simple andcost-effective manner.

The object is also achieved by an expansion valve operable by a steppermotor, the expansion valve comprising: a housing; a hollow shaftarranged in the housing; a valve base element that supports the hollowshaft and closes the housing; a rotor that is drivable by a stator; acenter spool that is arranged within the hollow shaft and drivable bythe rotor so that a rotating movement of the spool is transferable by athreaded connection into an axial movement for opening and closing theexpansion valve; and a sleeve element that includes respectively atleast a portion of the center spool, a compression spring and a forcetransfer element in a receiving portion and that includes a valveneedle, wherein the receiving portion of the sleeve element is closed bya bushing, wherein the spool is made from a first material and thebushing is at least partially made from a second material that differsfrom the first material, wherein the second material has a lowerhardness than the first material.

Since the sleeve element includes a valve needle and a receivingportion, this means the valve needle body is configured sleeve shaped, aparticularly compact configuration of the expansion valve can beachieved. This is in particular caused by the fact that elementsrequired for the force transmission to the valve needle can be arrangedin the receiving portion in a space saving manner.

During operation components are provided that perform a rotatingmovement and components that do not perform a rotating movement. Inparticular the spool performs a rotating movement, whereas the sleeveelement is not supposed to perform any rotation at all. A contact ofrotating elements with elements that do not rotate wears the elements.

The expansion valve according to the invention solves this problem inthat a selected tribological pairing is provided between contactingelements that move relative to each other. Thus, wear can be controlledso that the wear primarily occurs at one of the components involved.Additionally, this component can be optionally provided as a wear partthat can be replaced easily.

Thus, the bushing that closes the sleeve element can be a wear componentthat is easily replaceable. When the bushing is worn it can be replacedeasily and not the entire sleeve element including the valve needle hasto be replaced. Thus, maintenance cost can be reduced significantly.

The tribological pairing is selected so that the bushing is made from asofter material, this means a material with a reduced hardness comparedto the first material. Thus, the wear occurs primarily at the bushing.Though there may be an option to replace the bushing, the bushing isadvantageously sized so that it can wear over the life of the valve.

Overall, the expansion valve according to the invention provides acompact configuration with an engineering design that is configured fora targeted and controlled wear. The wear elements themselves can bereplaceable in a simple manner.

The bushing is pressed in particular into the sleeve element, this meansit is connected by a press fit.

A bushing according to the instant invention is an annular or hollowcylindrical element. Advantageously, however, the sleeve element is ahollow cylindrical element that is characterized in that it extendsfurther in the axial direction of the rotation axis than the annularelement. Accordingly, a hollow cylindrical wear element provides morewearable material than an annular wear element.

According to an advantageous embodiment of the invention the firstmaterial and the second material are metals or metal alloys.

According to an advantageous embodiment of the invention the secondmaterial is a copper alloy, advantageously brass and the first materialis steel, in particular stainless steel.

Particularly advantageously the second material is a sinter material,e.g. sinter bronze. Sinter materials have a plethora of pores that canbe filled with lubricants. For example, 10 to 40 volume percent,advantageously 15 to 30 volume percent of the bushing can then be formedby the pores.

In particular the material pairing of stainless steel and bronzeprovides a good balance between wear and production cost. On the onehand side the second material must not be too soft in order not to weartoo quickly and on the other hand side the second material must not betoo hard so that the element made from the first material does not getdamaged.

Particularly advantageously the force transmission element is made fromthe first material, e.g. stainless steel. Furthermore the sleeve elementis advantageously made from the first material, thus made from stainlesssteel as well.

According to an advantageous embodiment of the invention the forcetransmission element includes a head portion and a shaft portion,wherein the force transmission element is arranged so that a contact fortransferring axial forces from the center spool is punctiform in acenter portion of the head portion.

This punctiform transmission keeps the contact surface for transmittingthe torque between the spool and the force transmission element at aminimum. Due to the minimized small contact surface the spool slipsduring rotation and the force transmission element is not caused torotate. On the other hand, side axial forces can also be reliablytransferred from the spool to the force transmission element through thepunctiform contact.

This means torque is interrupted at the contact surface between theforce transmission element and the center spool. A torque impacts therotor that is driven by the stator wherein the torque is transferrede.g. through friction locking through the adapter to the spool. Thethreaded connection of the spool transposes the rotating movement intoan axial movement of the spool. Thus, only the axial movement at thevalve needle is desirable, this means a rotation of the valve needle atthis location is undesirable.

According to an advantageous embodiment of the invention the compressionspring is arranged in portions on an enveloping surface of the shaftportion of the force transmission element.

Since the compression spring is arranged on the enveloping surface ofthe shaft portion the compression spring is supported on its inside bythe shaft portion. On the other hand side, the compression spring issupported on the outside by the inner surface of the receiving portionof the sleeve element. This means that the compression spring isreliably supported between the shaft portion of the force transmissionelement and the receiving portion of the sleeve element.

Thus, the compression spring does not have to contact the two elements.It is also conceivable that a clearance between the enveloping surfaceof the shaft portion and the compression spring is provided as well asbetween the compression spring and the inner portion of the receivingportion. However, the compression spring is supported at a distance thatis long enough so that a kinking during compression of the spring isavoided.

According to an advantageous embodiment the compression spring is acylindrical coil spring.

Thus, the compression spring has low fabrication cost and can bereliably arranged about the enveloping surface of the shaft portion.

According to an advantageous embodiment of the invention an axial lengthof the shaft is long enough so that the shaft portion comes in contactwith a sleeve base of the sleeve element when the axial force exceeds alevel that causes the compression spring to be compressed by apredetermined amount of spring travel.

This means an axial force can be transferred directly from forcetransmission element to the sleeve base when the compression spring iscompressed by the predetermined amount of spring travel. Thus, a maximumstroke limitation can be provided when the mechanical stop, this meansthe spool stop structure fails or when the valve is overloaded.

Thus, the force transmission element performs several functions as well.First of all, the force transmission element facilitates a torquedecupling of the sleeve element from the spool. Furthermore, the forcetransmission element or its shaft portion supports the compressionspring in axial directions and thus prevents a kinking or generally anasymmetrical deformation of the compression spring. Furthermore, theshaft portion provides the limitation of the maximum stroke describedsupra.

According to an advantageous embodiment of the invention the spoolincludes a plunger shaped end portion that is configured and arranged sothat the end portion contacts the force transmission element in order totransfer axial forces, wherein an upper portion of the plunger shapedend portion comes in frictional contact with the bushing.

This means that a lower portion, more precisely a bottom side of theplunger shaped end portion comes in contact with the force transmissionelement and an upper portion of the plunger shaped end portion comesinto frictional contact with the bushing. Thus, the plunger shaped endportion is arranged between the bushing and the force transmissionelement

According to an advantageous embodiment of the invention the receivingportion is configured so that it receives the bushing, the plungershaped end portion, the compression spring and the force transmissionelement in its entirety.

The compression spring is arranged in a lower portion of the receivingportion, this means directly above the sleeve bottom. The forcetransmission element is arranged above the compression spring and theplunger shaped end portion of the spool is arranged above the forcetransmission element. The bushing is arranged above the plunger shapedend portion which closes the receiving portion overall.

This provides a particularly compact embodiment of the expansion valve.

According to an advantageous embodiment of the invention the expansionvalve includes a valve seat wherein the valve base element is integrallyprovided in one piece and receives portions of the valve seat, thesleeve element, and the hollow shaft.

Thus, the valve base element is configured as a replaceable valvecartridge. Since only the valve base element has to be removed from avalve installation cavity a simplified valve replacement is facilitated.Furthermore, also the valve becomes more compact since a plurality offunctions is intergraded into the valve base element.

Furthermore, providing the valve base element integrally in one pieceoffers the option to integrate the valve in a customer specificinstallation space by adapting only one component, thus the exterior ofthe valve base element. This helps to reduce cost since identicalcomponents can be used for various expansion valves. Furthermore, thecomponent count is reduced which reduces costs even further. Assemblycomplexity of the expansion valve is reduced as well.

According to an advantageous embodiment of the invention the valve baseelement includes a valve seat receiving portion in an upper portion thatis configured to receive a hollow shaft and the sleeve element.

Thus, the valve base element includes receiving portions that facilitateintegrating the elements of the expansion valve into the valve baseelement in a simple manner.

According to an advantageous embodiment of the invention the sleeveelement is arranged in the receiving portion at least partially withinthe hollow shaft.

The receiving portion reduces the installation space in an axialdirection of the expansion valve.

According to an advantageous embodiment of the invention the forcetransmission element is configured so that it does not receive anytorque or only a limited amount of torque from the spool.

This limitation is provided at the punctiform contact surface betweenthe force transmission element and the center spool.

According to an advantageous embodiment of the invention the expansionvalve includes a spool stopper structure that limits the rotatingmovement of the spool between an upper end position and a lower endposition.

According to an advantageous embodiment of the invention the spoolstopper structure is configured by a cooperation of a spiral body and astop body.

The object is also achieved by an expansion valve operable by a steppermotor, the expansion valve comprising a housing; a hollow shaft that isarranged at the housing; a valve base element that supports the hollowshaft and closes the housing; a rotor that is drivable by a stator; acenter spool that is arranged within the hollow shaft and drivable bythe rotor so that a rotating movement of the spool is transferablethrough a threaded connection into an axial movement for opening andclosing the expansion valve; and a sleeve element that includes a valveneedle that is pressable into a valve seat, wherein the valve baseelement is a body that is integrally provided in one piece and at leastpartially receives the valve seat, the sleeve element and the hollowshaft.

The valve base element is therefore configured as a valve cartridge.This has the advantage of simplified valve replacement since only thevalve base element has to be removed from the valve installation space.On the other hand side, a particularly compact configuration can beachieved since a plurality of functions is integrated in the valvecartridge, this means in the valve base element.

Additionally, a valve base element that is integrally provided in onepiece offers the option to integrate the valve into a customer specificinstallation space by only adapting one component. Thus, a plethora ofdifferent valves can be implemented that advantageously differ from eachother only with respect to the valve base elements.

Thus, the inner portion of the different valve base elements is alwaysconfigured identical so that the functional components in the interiorcan be installed into many different expansion valves. The outer shapeof the valve base elements, however, can be adapted to the customerspecific installation space so that the different valve base elementsdiffer in that respect.

This helps in particular to save fabrication costs since identicalcomponents can be used for different expansion valves. Complexity ofassembly of the expansion valve also decreases.

According to an advantageous embodiment of the invention, the valve baseelement includes a valve seat receiving portion in a lower portion and areceiving portion in an upper portion wherein the receiving portion isconfigured to receive the hollow shaft and the sleeve element.

Thus, the valve base element includes receiving portions that facilitatefunctionally integrating the necessary elements of the expansion valveinto the valve base element in a simple manner. The receiving portionalso reduces the installation space required in an axial direction ofthe expansion valve.

According to an advantageous embodiment of the invention the sleeveelement is at least partially arranged in the receiving portion withinthe hollow shaft.

This helps to save additional installation space. The receiving portioncan be arranged in a plane wherein the rotation axis R is an orthogonalof the plane. The hollow shaft is arranged in the receiving portion in aradially inward direction. Thereafter the sleeve element is arranged inthe radially inward direction, this means within the hollow shaft. Aportion of the center spool and/or a respective force transmissionelement are arranged in a radially inward direction.

This yields a very compact configuration. Since several elements areplaced into a plane a length in the axial direction can be reducedaccordingly. This means that the expansion valve can be shortened inlength compared to the prior art. In particular in automotiveinstallations installation space is severely limited so that shortervalves offer more installation options.

According to an advantageous embodiment of the invention the valve baseelement includes a housing seat which is respectively arranged andconfigured in a radially circumferential direction at a respective upperportion of the valve base element so that the housing seat receives andencloses the housing.

Thus, the housing can reliably enclose all components in its interior.

According to an advantageous embodiment of the invention the valve baseelement includes a lower seal receiving portion and an upper sealreceiving portion.

Arranging two different seal receiving portions helps to achievereliable sealing even when the valve base element is integrally providedin one piece.

According to an advantageous embodiment of the invention the valve baseelement incudes pressure balancing devices.

This means that the valve base element is configured so that pressurebalancing devices, e.g. pressure balancing channels are integratedtherein. Purposeful integration of pressure balancing channels orpressure balancing devices facilitates implementing the valve baseelement as a one piece component without impairing the functions of theexpansion valve.

According to an advantageous embodiment of the invention the housing anda side of the valve base element that is oriented towards the housingdefine an interior housing cavity wherein a first pressure balancingdevice is arranged as a first pressure balancing channel between thehousing interior and the fluid inlet cavity.

The first pressure balancing channel advantageously includes a firstchannel portion that is at least practically arranged in the valve baseelement and a second channel portion that is at least partially arrangedin the hollow shaft, wherein the first channel portion and the secondchannel portion are connected with one another by a circumferentialconnection portion.

During operations an imbalance between active forces in particular aboveand below the intermediary components has to be prevented, if possibleat all. This is achieved e.g. in that a high pressure provided at theinlet is conducted upward. Overall the pressure balancing channels areconfigured to prevent a pressure stasis in one of the cavities of theexpansion valve that could interfere with the function of the expansionvalve.

According to an advantageous embodiment of the invention the expansionvalve includes a second pressure balancing channel to provide pressurebalancing between a hollow shaft interior and the housing interior,wherein the hollow shaft interior is configured within the hollow shaft.

According to an advantageous embodiment of the invention the sleeveelement includes a receiving portion in which a plunger shaped endportion of the center spool, a compression spring and a forcetransmission element are received in their entirety, wherein thereceiving portion is arranged entirely within the valve base elementviewed in cross section.

This helps to save installation space. The hollow shaft is arranged in aradially inward direction in the receiving portion. The sleeve elementis arranged in a radially inward direction, this means within the hollowshaft. The plunger shaped end portion of the center spool, thecompression spring, and the force transmission element are arranged in aradially inward direction.

This yields a particularly compact configuration. Since plural elementsare placed in one plane a length in the axial direction can be reduced.

According to an advantageous embodiment of the invention the expansionvalve includes a third pressure balancing channel that is arrangedbetween a receiving portion of the sleeve element and a lower interiorportion of the valve base element wherein the valve needle is arrangedaxially moveable in the interior of the valve base element.

The third pressure balancing channel provides pressure balancing betweena space formed in the receiving portion of the sleeve element and alower interior portion of the valve base element. The lower interiorportion of the valve base element is in turn connected through a fluidbore hole with the fluid inlet cavity so that pressure balancing throughthe fluid bore hole can occur.

Thus, sufficient pressure balancing between all spaces that areconfigured or arranged within and also partially adjacent to theexpansion valve is achieved reliably with a simple engineeringconfiguration.

According to an advantageous embodiment of the invention the forcetransmission element includes a head portion and a shaft portion,wherein the force transmission element is arranged so that a contactwith the center spool is provided punctiform in a center portion of thehead portion.

The punctiform contact surface between the spool and the forcetransmission element transfers very little torque or no torque at all.Therefore the spool slips during rotation and the force transmissionelement is not caused to rotate. Axial forces, however, can also betransferred reliably from the spool to the force transmission element.Therefore, a torque interruption occurs at the contact surface betweenthe force transmission element and the center spool.

According to an advantageous embodiment of the invention the compressionspring is arranged in portions on an enveloping surface of the shaftportion of the force transmission element.

Since the compression spring is arranged on the enveloping surface ofthe shaft portion the compression spring is supported on the one handside on the shaft portion. On the other hand side the compression springis supported on the outside by the inner surface of the receivingportion of the sleeve element.

Thus, the compression spring does not have to contact both elements.Rather it is also conceivable that a clearance is configured between theenveloping surface of the shaft portion and the compression spring andbetween the compression spring and the inner surface of the receivingportion. However, the compression spring is supported so that a wedgingis prevented when the spring is compressed.

According to an advantageous embodiment of the invention the compressionspring is a cylindrical coil spring.

Since the compression spring is a cylindrical coil spring fabrication isparticularly cost effective and the compression spring can be reliablyarranged about the enveloping surface of the shaft portion.

According to an advantageous embodiment of the invention the shaftportion is long enough so that the shaft portion comes in contact with asleeve base of the sleeve element when an axial force is exceeded thatleads to a compression of the compression spring by a predeterminedspring travel.

This means an axial force is statically transferrable from the forcetransmission element to the sleeve base when the compression spring iscompressed by a predetermined spring travel. Thus, a maximum strokelimitation is provided when the mechanical stop fails, this means thespool stopper structure fails or when an overload of the valve occurs.

Thus, also the transmission element performs plural functions. First ofall the transmission element facilitates a torque decupling of thesleeve element from the spool. Furthermore, the transmission element orits shaft portion supports the compression spring in axial directionsand thus prevents a kinking or generally an asymmetrical deformation ofthe compression spring. Furthermore, the shaft portion provides themaximum stroke limitation described supra.

The object is also achieved by an expansion valve configured to bedriven by a stepper motor and configured to be installed into a valveinstallation cavity, the expansion valve comprising: a housing; a hollowshaft that is arranged at the housing; a valve base element thatsupports the hollow shaft and that closes the housing; a rotor that isdrivable by a stator; and a center spool that is arranged within thehollow shaft and drivable by the rotor so that a rotating movement ofthe spool is transferable through a threaded connection into an axialmovement for opening and closing the expansion valve, wherein thehousing and a side of the valve base element that is oriented towardsthe housing define a housing cavity, wherein a hollow shaft cavity isconfigured within the hollow shaft, wherein a fluid inlet cavity isarranged adjacent to a side of the valve base element that is orientedaway from the housing in a condition where the expansion valve isinstalled in a valve installation cavity, wherein the housing cavity isconnected with the fluid inlet cavity through a first pressure balancingchannel in order to provide pressure balancing, wherein the firstpressure balancing channel includes a first channel portion that is atleast partially arranged in the valve base element and a second channelportion that is at least partially arranged in the hollow shaft, whereinthe first channel portion and the second channel portion are connectedwith each other through a circumferential connection portion.

Thus, the expansion valve includes a plurality of cavities that areconfigured within or adjacent to the expansion valve. An imbalancebetween acting forces, in particular above and below intermediarycomponents have to be prevented in as far as possible. This is done e.g.by venting high pressure provided at the inlet in an upward direction.Overall, the pressure balancing channels prevent a pressure stasis inone or plural cavities of the expansion valve that could interfere withthe function of the expansion valve.

In assembled condition of the expansion valve the hollow shaft isarranged in the valve base element, more precisely in one or thereceiving portion of the valve base element. The first channel portionis at least partially arranged in the valve base element and the secondchannel portion is at least partially arranged in the hollow shaft.

In order to provide pressure balancing between the first channel portionand the second channel portion, the first channel portion and the secondchannel portion need to be flow connected. The flow connection isprovided through the circumferential connection portion. Since theconnection portion is configured as a circumferential connection portionthat forms the necessary flow connection between the two portions thevalve base element and the hollow shaft do not have to be aligned witheach other during assembly. This facilitates assembly and assemblyerrors can be avoided that could lead to a failure of the expansionvalve.

According to an advantageous embodiment of the invention thecircumferential connection portion is a circumferential relief groovewhich is arranged at an inner circumference of a receiving portion ofthe valve base element.

The circumferential relief groove provides a reliable fluid connectionbetween the first channel portion and the second channel portion.

According to an advantageous embodiment of the invention thecircumferential connection portion is a circumferential bevel that isarranged at an outer circumference of the hollow shaft.

This has in particular the advantage that the bevel is producible in asimpler and more cost-effective manner than the circumferential reliefgroove in the receiving portion.

When a particularly quick pressure balancing is required acircumferential relief groove and a circumferential bevel can bearranged.

According to an advantageous embodiment of the invention the secondchannel portion is configured as a longitudinal groove that extends inthe hollow shaft from a portion that is arranged in the valve baseelement to a portion that is not arranged in the valve base element.

The longitudinal groove is producible in a particularly simple manner,wherein the longitudinal groove is in particular a longitudinal groovein which the slide ring described supra moves in an axial direction.Thus, the longitudinal groove performs a double function since it is notonly configured as a second channel portion but also supports the slidering that performs functions of the expansion valve as part of the spoolstopper structure.

According to an advantageous embodiment of the invention the expansionvalve includes a second pressure balancing channel to provide pressurebalancing between the hollow shaft cavity and the housing cavity whereinthe second pressure balancing channel is at least partially formed bythe second channel portion.

Put differently portions of the second channel portion also formportions of the second pressure balancing channel.

According to a second embodiment of the invention a second pressurebalancing channel is arranged in a portion of a maximum radial extensionof the longitudinal groove and of the hollow shaft cavity.

This means that the second pressure balancing channel is arranged at abase of the longitudinal groove. In particular the pressure balancingchannel is an opening in a base of the longitudinal groove.

Thus, the longitudinal groove can provide pressure balancing between thehollow shaft interior and the housing interior not only as a secondchannel portion but also as a portion of the second balancing channel inaddition to pressure balancing between the fluid inlet cavity and thehousing cavity.

When introducing the longitudinal groove into the hollow shaft providedwith the hollow shaft cavity the second channel portion of the firstpressure balancing channel and the second pressure balancing channel canbe formed simultaneously.

According to an advantageous embodiment of the invention the expansionvalve includes an adapter element that is arranged between the rotor andthe spool to transfer a torque from the rotor to the spool wherein theadapter element includes at least one off center opening that isarranged so that it balances a pressure in the housing cavity above theadapter element and below the adapter element.

The off center opening in the adapter element facilitates balancing apressure within the housing cavity, namely between an upper portionabove the adapter element and a lower portion below the adapter elementin a quick and simple manner. This further increases functionalreliability of the expansion valve.

According to an advantageous embodiment of the invention the expansionvalve includes a third pressure balancing channel that is arrangedbetween a receiving portion of a sleeve element that includes a valveneedle of the expansion valve and a lower inner portion of the valvebase element in which the valve needle is arranged axially moveable andthat is connected through a fluid bore hole with the fluid inlet cavity.

The third pressure balancing channel thus provides pressure balancingbetween a cavity that is formed in the receiving portion of the sleeveelement and a cavity in a lower interior portion of the valve baseelement. The lower inner portion of the valve base element is in turnconnected through a fluid bore hole with the fluid inlet cavity so thata pressure compensation through the fluid bore hole can be performed atthis location as well.

Thus, a reliable and sufficiently pressure balancing is achieved throughall cavities that are formed or arranged within and partially alsoadjacent to the expansion valve, e.g. the fluid inlet cavity using asimple engineering design.

According to an advantageous embodiment of the invention a plungershaped end portion of the center spool, a compression spring and a forcetransmission element are also received in the receiving portion of thesleeve element.

This yields a particularly compact configuration of the expansion valvewhich, however, can perform all functions.

According to an advantageous embodiment of the invention the forcetransmission element is configured and arranged so that it transfersaxial forces from the center spool through the compression spring to thesleeve element through a contact with the center spool, wherein theforce transmission element has a mushroom shaped cross section.

According to an advantageous embodiment of the invention the forcetransmission element includes a head portion and a shaft portion,wherein the force transmission element is configured so that the contactwith the center spool is punctiform in a central portion of the headportion.

Due to the punctiform contact surface between the spool and the forcetransmission element no torque or hardly any torque can be transferred.Therefore the spool slips during rotation and the force transmissionelement is not caused to rotate. Axial forces, however, can also betransferred reliably by the punctiform contact surfaces from the spoolto the force transmission element. Therefore, there is a torqueinterruption at the contact surface between the force transmissionelement and the center spool.

According to an advantageous embodiment of the invention the expansionvalve includes a valve seat, wherein the valve base element is anelement that is integrally provided in one piece and that receives thevalve seat, the sleeve element, and the hollow shaft at least inportions.

Thus, the valve base element is configured as a cartridge. On the onehand side this has the advantage of simplified valve replacement sinceonly the valve base element has to be removed from the valveinstallation cavity. However a particularly high level of compactnesscan be achieved since a plurality of functions is integrated in thevalve cartridge, this means in the valve baes element.

Furthermore, a valve base element of this type that is configuredintegrally in one piece offers the option to integrate the valve into acustomer specific installation space by merely adapting one component.This saves in particular fabrication costs since identical componentscan be used for various expansion valves. Additionally, complexityduring assembly of the expansion valve decreases.

According to an advantageous embodiment of the invention the valve baseelement includes a lower seal receiving portion and an upper sealreceiving portion.

Arranging two different seal receiving portions facilitates achievingreliable sealing also for a valve base element that is integrallyprovided in one piece.

The object is furthermore achieved by a method for producing anexpansion valve, the method compromising: providing the hollow shaft;and introducing a longitudinal groove into the hollow shaft.

According to an advantageous embodiment of the invention the secondpressure balancing channel is formed in the hollow shaft whenintroducing the longitudinal groove.

Simultaneous introduction of the second pressure balancing channelallows to omit an otherwise additionally required process step forseparately introducing the second pressure balancing channel

BRIEF DESCRIPTION OF THE DRAWINGS

The invention is now described in more detail based on embodiments withreference to the appended a drawing figure. Thus, additionaladvantageous embodiments and feature combinations of the invention canalso be derived from the subsequent description and the entirety of thepatent claims. The invention is now described in more detail based onembodiments with reference to the appended drawing figure, wherein:

FIG. 1 illustrates a longitudinal sectional view of an expansion valveaccording to the invention in a condition installed in a valveinstallation space;

FIG. 2 illustrates a detailed longitudinal sectional view of a movementmechanism of the expansion valve according to the invention;

FIG. 3 illustrates a schematic view of an adapter element of theexpansion valve according to the invention;

FIG. 4 illustrates a detailed longitudinal sectional view of an adapterelement and a rotor of the expansion valve according to the invention;

FIG. 5 illustrates a schematic view of a support spring of the expansionvalve according to the invention;

FIG. 6 illustrates a schematic view of a sliding ring of the expansionvalve according to the invention;

FIG. 7 illustrates a top view of the sliding ring of FIG. 6;

FIG. 8 illustrates a schematic view of a hollow shaft of the expansionvalve according to the invention;

FIG. 9 illustrates a schematic view of the spool stopper geometry of theexpansion valve according to the invention;

FIG. 10 illustrates a longitudinal sectional view of a forcetransmission and torque limiting device of the expansion valve accordingto the invention;

FIG. 11 illustrates a longitudinal sectional view of a sleeve element ofthe expansion valve according to the invention;

FIG. 12 illustrates a schematic view of a force transmission element ofthe expansion valve according to the invention;

FIG. 13 illustrates a schematic representation of a compression springof the expansion valve;

FIG. 14 illustrates a longitudinal sectional view of a valve baseelement of the expansion valve according to the invention;

FIG. 15 illustrates a schematic view of the valve base element of FIG.14;

FIG. 16 illustrates a detailed longitudinal sectional view of the valvebase element according to the invention; and

FIG. 17 illustrates a detailed longitudinal sectional view of a hollowshaft of the expansion valve according to the invention.

DETAILED DESCRIPTION OF THE INVENTION

FIG. 1 illustrates a longitudinal sectional view of an embodiment of anexpansion valve 1 according to the invention. For illustration purposesa top side 2 and a bottom side 3 is defined in FIG. 1. The top side 2and the bottom side 3 are also respectively used for describingindividual components shown in FIG. 1 in an overall arrangement.

The expansion valve 1 includes a valve base element 5 and a housing 4.FIG. 1 illustrates the expansion valve 1 in a condition where theexpansion valve is installed in a valve installation cavity 43. Thevalve installation cavity 43 is a general cavity where the expansionvalve is installed.

Since the valve base element 5 is an element that is integrally providedin one piece the element can be inserted into the valve installationcavity 43 as a cartridge. Accordingly, the entire expansion valve 1 isinstallable into and removable from the valve installation cavity in asimple manner.

A fluid channel 46 is configured in the expansion valve 1 that isinstalled in the valve installation cavity 43. The fluid channel 46extends in FIG. 1 from a lateral portion on a left side of FIG. 1 in adirection towards the valve base element 5 and forms a fluid inletcavity 27 about a lower portion of the valve base element 3, this meanstowards the bottom side 3.

The fluid inlet cavity 27 is connected through fluid bore holes 40 witha lower inner portion 42 of the valve base element 5. A valve needle 20of the expansion valve 1 is also arranged in the lower inner portion 42.

When the expansion valve 1 is opened the fluid channel is formed fromthe lateral portion of the expansion valve through the fluid inletcavity 27 through the fluid bore hole 40 through the lower interiorportion 42 of the valve base element 5 and through a valve opening thatis closeable by the valve needle 20 towards a portion below theexpansion valve 1.

The housing 4 is arranged at an upper side, this means towards the topside 2 of the valve base element 5. In particular the housing 4 isconfigured sleeve shaped.

All functional elements or components of the expansion valve 1 arearranged within the housing 4 or within the valve base element 5. Thehousing 4 is enveloped by a stepper motor or a stator of a steppermotor.

The valve base element 5 closes the housing 4 at a bottom side 3. Thehousing 4 includes a rotor 6 of the stepper motor which imparts itsrotation upon a center spool 8.

In FIG. 1 the rotation is transferred from the rotor 6 through anadapter element 13 to the center spool 8. The center spool 8 includes anexternal thread that is connected with an inner thread of a hollow shaft7 forming a threaded connection 9.

The threaded connection 9 moves the center spool 8 axially downwardalong a rotation axis R, this means from the top side 2 to the bottomside 3 or upward, this means from the bottom side 3 to the top side 2.Therefore this movement mechanism transposes the rotating movement ofthe rotor 6 into an axial movement.

A spiral body 12 is configured about the hollow shaft 7. The spiral body12 is configured as a support spring 12 in the embodiment illustrated inFIG. 1. Therefore, the same reference numeral 12 is used for the supportspring and for the spiral body.

A stop element extends in the spiral body 12, this means in a threadturn 16. At this location the stop body is configured as a sliding ring17.

The support spring 12 and the sliding ring 17 form a spool stoppergeometry that predetermines an upper axial end position and a loweraxial end position of the center spool 8. The function of the spoolstopper structure is described in more detail with reference to FIG. 2and FIG. 9.

The lower portion, this means the portion towards the bottom side 3 ofthe center spool 8 is received in a sleeve element 21. The sleeveelement 21 itself is received in the valve base element 5. Additionally,also a lower portion of the hollow shaft 7 is received in the valve baseelement 5.

In particular the sleeve element 21 is partially received in the hollowshaft 7 as illustrated in FIG. 1, wherein the hollow shaft is in turnpartially received in the valve base element 5. This means that an innercircumferential surface of the valve base element 5 is in contact withan outer circumferential surface of the hollow shaft 7. Furthermore, aninner circumferential surface of the hollow shaft 7 is in contact withan outer circumferential surface of the sleeve element 21.

The sleeve element 21 includes the valve needle 20 in a lower portion.The sleeve element 21 is an element that is integrally provided in onepiece. This means the valve needle 20 is configured sleeve shaped.

The valve needle 20 is arranged in a valve seat 24, wherein an openingthrough the valve seat 34 is exposed by lifting the valve needle fromthe valve seat 34 towards the top side 2 so that a fluid can flowthrough the valve seat 34.

FIG. 1 shows the valve needle 20 in an applied condition where the valveneedle presses onto the valve seat in a sealing manner.

Elements are arranged within the sleeve element 21 wherein the elementsprovide force transmission and torque limiting between the spool 8 andthe sleeve element 21. These elements are described in more detail withreference to FIG. 10.

FIG. 2 illustrates an upper portion of the expansion valve 1 in moredetail. In particular FIG. 2 shows the rotor 6 that is connected by theadapter 13 with the center spool 8 that is in turn connected through thethreaded connection 9 with the hollow shaft 7.

As evident from FIG. 2 the support spring 12 is arranged at anenveloping surface 10 of the hollow shaft 7. In particular the supportspring 12 is the coil spring that is illustrated in FIG. 5. The coilspring includes a first stop element 14 and a second stop element 15.The two stop elements 14,15 are arranged at respective ends of thesupport spring 12 that is configured as a coil spring. In particular thefirst stop element 14 extends from an upper end of the coil springaxially upward, whereas the second stop element 15 extends axiallydownward from a lower end of the support spring 12.

As evident from FIG. 2 the first stop element 14 is connected with theadapter element 13. This means that the support spring 12 or the spiralbody 12 can co-rotate with the adapter element 13. For this purpose theadapter element 13 includes off center openings 13 c (cf. FIG. 3) inwhich the first stop element 14 can be inserted or is inserted.

As illustrated in FIG. 1 the second stop element 15 is oriented in adirection towards the valve base element 5. Advantageously the secondstop element 15 can slip on the base element 5 during operations.Alternatively, a circular groove can be configured in the base element 5wherein the second stop element 15 of the spiral body 12 or of thesupport spring 12 extends and runs in the circular groove.

As illustrated in FIG. 3 the adapter element 13 includes a plate shapedbase portion 13 a and a receiving portion 13 b for the center spool 8.Thus, the receiving portion 13 b extends centrally from the plate shapedbase portion 13 a in an axial direction of the rotation axis R (cf. FIG.4.).

The rotor 6, the adapter element 13, the spiral body 12 and the centerspool 8 rotate about the rotation axis R.

The adapter element 13 includes plural off center openings 13 c that areconfigured in the plate shaped base portion 13 a off center, this meansremote from the center. FIG. 3 illustrates four off center openings 13 cconfigured as slotted holes at an outer circumference of the plate shapebase portion 13 a. Forming the off-center openings 13 c as slotted holesprovides in particular fabrication advantages.

The upper end portion, this means the first stop element 14 of thesupport spring 12 extends into one of the off-center openings 13 c. Theremaining off center openings 13 c in the plate shaped base portion 13 aof the adapter element 13 can be used e.g. to provide sufficientpressure balancing between a housing cavity 28 above the adapter element13 and a housing cavity 28 below the adapter element 13.

A center pass through opening 13 d is formed within the receivingportion 13 d of the adapter element 13 wherein an upper portion of thecenter spool 8 is receivable in the central passthrough opening 13 d.This upper portion of the spool 8 is configured complimentary to thecentral passthrough opening 13 d viewed in cross section. Viewed incross section in this context means both components are viewed along therotation axis R.

For the purpose of force transmission, it is conceivable that bothelements do not form a circular shape in cross section but a shape thatis not rotation symmetrical. Thus, a simple force transmission can beperformed from the adapter element 13 onto the center spool 8.Accordingly, the center passthrough opening 13 d can be configuredpolygonal advantageously rectangular. Overall, however any non-rotationsymmetrical configuration is conceivable to transfer the torque.Advantageously, however the cross section has a circular shape and theforce transmission is provided e.g. by a weld.

As illustrated in FIG. 4 an outer circumference of the plate shaped baseportion 13 a is connected with the rotor 6. Thus, the torque of therotor 6 is transmitted to the adapter element 13 as evident from FIGS. 4and 2 an upper portion of the rotor 6 includes a stop so that theadapter element 13 cannot slip through the rotor 6. This is advantageousin particular during assembly and helps to avoid assembly errors.

The connection between rotor 6 and adapter element 13 can be bonded,form locking, or friction locking. In this context it is essential thata torque can be transferred from the rotor 6 upon the adapter element13. As a matter of principle, it is also conceivable the adapter element13 and the rotor 6 are configured as an integral one-piece component.

FIG. 2 illustrates the sliding ring 17 in a sectional view wherein thesliding ring 17 extends in the thread turn 16 of the support spring 12.

A larger representation of the sliding ring 17 is provided in FIGS. 6and 7. This shows that the sliding ring 17 is configured as a spiralshaped element. In particular the sliding ring 17 is configured as acylindrical spiral that is wound about the rotation axis R in installedcondition.

As illustrated FIG. 6 the sliding ring 17 includes an upper end 17 a anda lower end 17 b. The upper end 17 a and the lower end 17 b can overlapso that a spiral shaped body with more than one winding is formed. Thisoverlap of the ends and a number of windings of the support spring 12limits a maximum number of revolutions of the center spool 8.

The sliding ring 17 includes a radially inward extending protrusion 18at one end, in this embodiment at the lower end 17 b. As evident fromFIG. 1 this protrusion 18 extends in the hollow shaft 7. More preciselythe protrusion 18 of the sliding ring 17 is insertable or insertedduring operation into a longitudinal groove 11 of the hollow shaft 7.This longitudinal groove 11 is evident from FIGS. 8 and 9.

FIG. 8 illustrates a schematic representation of the hollow shaft 7. Thehollow shaft 7 is configured as a hollow cylindrical element andenvelops a hollow shaft cavity 29. As evident from FIG. 8 a hollow shaftbore hole 31 is arranged at an upper portion of the hollow shaft 7,wherein the center spool 8 is insertable into the hollow shaft bore hole31. The longitudinal grove 11 is arranged at the enveloping surface 10,wherein the longitudinal groove 11 extends in the axial direction ininstalled position parallel to the rotation axis R. The longitudinalgroove 11 is advantageously open in downward direction, this meanstowards the bottom side 3. Alternatively, the longitudinal groove canalso be limited in the upward direction and in the downward direction asillustrated in FIG. 9.

In installed condition the protrusion 18 of the sliding ring 17 isarranged in the longitudinal groove 11. Therefore, the sliding ring 17cannot rotate relative to the hollow shaft 7. This means that thelongitudinal groove 11 and the protrusion 18 provide a rotation safetyof the sliding ring 17. The sliding ring 17 can only move axially upwardalong the longitudinal groove 11 and axially downward along thelongitudinal groove 11.

When the rotor 6 rotates during operation and the adapter element 13transfers this rotating movement upon the support spring 12 through theoff center opening 13 c the support ring 12 rotates relative to thehollow shaft 7 as well as relative to the sliding ring 17 that isaxially secured in the hollow shaft 7, this means in the longitudinalgroove 11. The rotation of the support spring 12 causes the sliding ring17 to move in the thread turn 16 of the support spring 12. Accordingly,the sliding ring 17 moves up and down along the thread turn 16. It isevident the in particular from FIG. 9 that the spiral shaped slidingring 17 extends in the thread turn 16 of the support spring 12.

The spool stopper geometry of the instant invention is formed by thesliding ring 17 only moving far enough upward along the thread turn 16until the sliding ring 17 contacts the first stop element 14 of thesupport spring 12 with the upper end 17 a of the sliding ring 17.

It is a function of the pitch of the support spring or the spiral body12 whether the upper end position or the lower end position of thecenter spool 8 is defined. When the thread pitch of the spool 8 differsfrom the thread pitch of the spiral body 12 the first stop element 14defines the upper end position of the center spool 8. When the spool 8and the spiral body 12 have identical pitch orientations the first stopelement 14 defines the lower end position of the center spool 8.Advantageously the thread pitch of the center spool 8 and the threadpitch of the central spiral body 12 are identical.

As soon as the sliding ring 17 contacts the first stop element 14 nofurther rotation of the support spring 12 relative to the sliding ring17 is possible in this direction of rotation. More precisely therotation of the adapter element 13 is slowed down in that the supportspring 12 blocks, this means that the support spring 12 cannot rotateany further since it is blocked by the sliding ring 17.

The braking force is transferred from the longitudinal groove 11 of thehollow shaft 7 onto the protrusion 18 of the sliding ring 17 and fromthe protrusion 18 to an upper end 17 a of the sliding ring 17 to thefirst stop element 14 of the support spring 12 and from the first stopelement 14 to the off center opening 13 c of the adapter element 13. Acertain amount of rotation of the individual elements can certainlyoccur wherein the rotation leads to an attenuation of the braking forcewhich can be desirable. This occurs in particular at the lower contactpoint.

FIG. 9 illustrates the sliding ring 17 at this lower contact point. Asevident from FIG. 9 the support spring 12 has rotated far enoughrelative to the sliding ring 17 and the hollow shaft 7 so that thesliding ring 17 has moved to a lower end of the support spring 12. Therethe lower end 17 b of the sliding ring 17 comes in contact with thesecond stop element 15 of the support spring 12. Thus, the brake forceflow runs from the longitudinal groove 11 of the hollow shat 7 to thelower end 17 b of the sliding ring 17 and from the lower end 17 b of thesliding ring 17 to the lower second stop element 15 of the supportspring 17. From this stop element 15 the brake force runs along theentire support spring 12 to the first stop element 14 and then again tothe off center opening 13 c of the adapter element 13.

This means that contrary to the upper contact point the brake forceflows along the entire support spring 12. When the support spring 12 isconfigured as a rigid spiral body there is no attenuation or only anegligible attenuation of the braking force impacting the center spool8.

Depending on the pitch of the spiral body the lower end position or theupper end position of the spool 8 is reached when the first stop element14 contacts the upper end 17 a of the sliding ring 17 and the upper orthe lower end position of the spool 8 is reached when the second stopelement 15 contacts the lower end 17 b of the sliding ring 17 optionallyplus a maximum torsion angle of the spiral body 12.

FIGS. 10-13 illustrate the force transmission mechanism from the spool 8to the sleeve element 21 or the valve needle 20. The center spool 8includes a plunger shaped end portion 22 that is configured at a lowerend of the spool 8.

This plunger shaped end portion 22 is received in the sleeve element 21.More precisely the plunger shaped end portion is received in a receivingportion 21 a of the sleeve element 21. As illustrated in FIG. 10 acompression spring 24 and a force transmission element 23 are arrangedin the receiving portion 21 a.

The compression spring 24 that is illustrated in an enlarged view inFIG. 13 is in contact with a sleeve base 21 b of the sleeve element 21.The compression spring 24 is a cylindrical coil spring that contacts thesleeve base 21 b of the sleeve element 21 with a lower portion.

As illustrated in FIG. 12 the force transmission element 23 includes ahead portion 23 a and a shaft portion. The shaft portion 23 b in turnincludes an enveloping surface 23 c.

The shaft portion 23 b is arrangeable within the compression spring 24.Put differently the compression spring is supported in an inwarddirection by the enveloping surface 23 c of the shaft portion 23 b. Theforce transmission element 23 thus functions as a support element forthe compression spring 24, wherein a kinking of the compression spring24 is also prevented by the inner circumferential surface of thereceiving portion 21 a. Overall the compression spring 24 is supportedby the receiving portion 21 a and the receiving portion 21 b.

As evident from FIG. 12 the force transmission element 23 has a mushroomshape overall, this means that the head portion 23 a is configured e.g.semi-spherical and includes an outer circumference that is larger thanthe outer circumference of the shaft portion 23 b. Put differently thehead portion 23 a is configured mushroom head shaped and the shaftportion 23 b is configured mushroom stem shaped.

Since the head portion 23 a is wider a contact portion is formed betweenthe force transmission element 23 and the compression spring 24. Thismeans that an upper portion of the compression spring 24 can come incontact with a lower portion of the head portion 23 a.

The mushroom head shape of the head portion 23 a furthermore has theadvantage that the contact portion to the mushroom shaped end portion 22is essentially punctiform. An axial force can be transferred throughthis punctiform contact portion, this means from a top (2) to a bottom(3) or from the bottom (3) to the top (2) quite well, whereas torque istransferred hardly at all. Thus, no substantial torque is transferred bythe plunger shaped end portion 22 to the force transmission element 23.Therefore, the force transmission element 23 can function as a torquelimiter.

When a rotating movement is transferred from the rotor 6 through theadapter element 13 onto the center spool 8, the plunger shaped endportion 22 moves upward or downward. When the plunger shaped end portion22 moves downward it presses against the force transmission element 23which presses onto the sleeve base 21 b with attenuation by thecompression spring 24 and thus presses onto the sleeve element 21 andthe valve needle 20. This means that the valve needle 20 is pressed in adirection towards the valve seat 24.

An upper portion towards the top side (2) of the sleeve element 21 isclosed by a bushing 24. The bushing 24 is configured hollow cylindricaland made from a different material than the spool 8. In particular, thefirst material from which the spool 8 is made is harder than the secondmaterial from which the bushing 44 is made. Thus, low friction betweenthe spool 8, thus the plunger shaped end portion 22 and the bushing 44can be achieved. This is advantageous and prevents that the valve needle24 co-rotates with the valve seat 34 for any length of time.

This means furthermore that controlled wear occurs at the secondmaterial that has lower hardness when friction occurs between the firstmaterial and the second material. This helps to control wear at theforce transmission arrangement or of the associated components.

The bushing 44, the sleeve element 21 with the valve needle 20 and theforce transmission element 23 rotate at the same speed as the spool 8until the valve needle 20 is restricted with respect to its axialmovement in the valve seat 34 and the effective torque is less thanbetween the bushing 44 and the spool 22 in their contact area.

Only when the braked static friction torque in the valve seat 34 islarge enough, the valve needle 20 is caused to stop. From then on thereis no relative movement between the spool 22 and the bushing 44. Therelative movement occurs at the face of the bushing 44 and then onlypartially at the inner enveloping surface of the bushing 44.

The main reason of the residual rotation of the spool 8 after the valveneedle 20 sits in the valve seat 34 is to provide reliable closing evenafter a longer run time. Thus, a reliable closing of the valve is alsoassured after years of wear. Therefore, the spool performs a residualrotation of several steps, e.g. 10 steps. This residual rotationrequires reliable torque de-coupling.

The advantage of using the bushing 44 lies in particular in thatcontrolled wear occurs with low friction relative to the spool 8.Therefore, neither the sleeve element 21 nor the center spool 8 wearout. Since the force transmission portion between the force transmissionelement 23 and the center spool 8 is kept at minimum through theparticular shape of the head portion 23 a no particularly high frictionoccurs at this location so that the force transmission element 23 canalso be fabricated from the first material.

The first material can be e.g. stainless steel and the second materialis e.g. a copper alloy, advantageously brass. The material pairing ofbrass and stainless steel is particularly advantageous. Since the sleeveelement 44 is rather long in its longitudinal direction, this meansalong the rotation axis R, a sufficient amount of material is providedthat can be removed from the sleeve element.

FIG. 14 illustrates a longitudinal sectional view of the valve baseelement 5. The valve base element 5 includes a side 5 a that is orientedtowards the housing 4, wherein the side 5 a is an upper side towards thetop side 2 of the valve base element 5. The valve base element 5includes a side 5 b that is oriented away from the housing 4 opposite tothe side 5 a that is oriented towards the housing 4.

As evident in FIG. 1, the fluid inlet cavity is configured adjacent tothe side 5 b of the valve base element 5 that is oriented away from thehousing 4 when the valve base element 5 is installed into the valveinstallation space 43.

The valve base element 5 further includes a receiving portion 33 inwhich the hollow shaft 7 is received that receives the sleeve element 21inside the hollow shaft 7 in assembled condition as illustrated in FIG.1.

A circumferential relief groove 32 is arranged in a lower portion of thereceiving portion.

A valve seat receiving portion 35 is arranged further down in the valvebase element 5. This valve seat receiving portion 35 provides a stop forthe valve seat 34 when the valve seat 34 is pushed into the valve baseelement 5 from above. This achieves a secure and defined arrangement ofthe valve seat 34.

A lower seal receiving portion 36 is configured at an outer lowerportion of the valve base element 5. As evident from FIG. 1 an annularseal element can be inserted into the seal receiving portion inassembled condition. The seal element seals the fluid inlet cavity 27against a portion of the fluid channel 46 that is arranged below theexpansion valve 1 and vice versa.

FIG. 14 shows an upper seal receiving portion 37 configured in a centerto upper portion of the valve base element 5. As evident from FIG. 1 theupper seal receiving portion 37 also includes an annular seal element inthe installed condition wherein the annular seal element seals inparticular the fluid inlet cavity 27 against ambient.

As also evident from FIGS. 14-16 a housing seat 39 is arranged at atopside 2 of the valve base element 5. The housing seat is in particulararranged in a radially circumferential manner at the upper portion ofthe valve base element 5 that is oriented towards the housing 4 so thatthe housing seat 39 can receive and close the housing 4. As illustratedin FIG. 1 a closing element e.g. provided as a ring can press thehousing 4 radially inward against the housing seat 39.

A plurality of pressure balancing channels 35, 36 and 41 is configuredwithin the expansion valve 1. A first pressure balancing channel 25connects the housing cavity 28 with the fluid inlet cavity 27 andbalances the pressure between both cavities.

The first pressure balancing channel 25 includes a first channel portion25 a and a second channel portion 25 b. The first channel portion 25 ais configured within the valve base element 5 as illustrated in FIGS. 14and 16. Overall the first channel portion 25 a is a bore hole thatextends from a side 5 b that is oriented away from the housing 4 intothe valve base element 5. The first channel portion 25 a is formed up tothe circumferential relief groove 32 of the valve base element 5. Thismeans that the bore hole extends into the relief groove 32. Thus, thefirst channel portion 25 a provides a connection from the side 5 b thatis oriented away from the housing 4 to the receiving portion 33 of thebase element 5.

In an assembled condition of expansion valve 1 the hollow shaft 7illustrated in FIG. 17 is received in this receiving portion 33. Thehollow shaft 7 includes the second channel portion 25 b that extends asa longitudinal groove 11 from a lower end of the hollow shaft 7 in anupward direction.

Advantageously the lower end 7 of the hollow shaft is configured as acircumferential bevel 38 so that the circumferential bevel 38 as well asthe circumferential relief groove 32 function as a connection portionbetween the first channel portion 25 a and the second channel portion 25b.

In general, a circumferential connection portion has in particular anadvantage in that no alignment has to be performed between the hollowshaft 7 and the valve base element 5. As a matter of principle, however,it would already suffice to arrange either of the circumferential reliefgroove or the circumferential bevel 38. Forming both elements, however,leads to a quicker pressure balancing.

Therefore the longitudinal groove 11 of the hollow shaft 7 serves adouble function. Thus, the longitudinal groove is used on the one handside to support the sliding ring 17 and on the other hand side it formsthe second channel portion 25 b that provides pressure balancing. Thisfunctions in particular in that the longitudinal groove 11 is opentowards the inner housing cavity 28. Therefore, pressure balancing isprovided between the fluid inlet cavity 27 and the inner housing cavity28.

A second pressure balancing channel 26 provides pressure balancingbetween the hollow shaft cavity 29 and the housing cavity 28. Thissecond pressure balancing channel 26 is evident in particular from FIG.17. This FIG. shows in particular that the second pressure balancingchannel 26 is formed in a portion of a maximum radial extension of thelongitudinal groove 11 and the hollow shaft cavity 29. This has inparticular an advantage in that the second pressure balancing channel 26can be produced simultaneously with introducing the longitudinal groove11 into the hollow shaft 7 with the hollow shaft cavity 29 withoutrequiring an additional process step.

In principle the second balancing channel 26 is an opening at a base ofthe longitudinal groove 11. This opening is connected with the hollowshaft interior 29 and the longitudinal groove 11 and therefore also withthe housing cavity 28. Furthermore, the second pressure balancingchannel 26 is formed in portions by the second channel portion 25 b ofthe first pressure balancing channel 25 or the pressure balancingchannels use common portions.

The expansion valve 1 further includes a third balancing channel 41.This third pressure balancing channel 41 is evident in particular fromFIG. 10 and connects the lower inner portion 42 of the valve baseelement 35 with the receiving portion 21 a of the sleeve element 21. Thelower inner portion 42 of the valve base element 5 is connected throughthe fluid bore holes 40 with the fluid inlet cavity 27 as evident fromFIG. 1.

All features described and shown in conjunction with individualembodiments according to the invention can also be used in differentcombinations to implement the invention and cause its advantageouseffects. The protective scope of the instant invention is defined by theappendant patent claims and is not limited by the features described inthe description or shown in the drawing figures.

The description describes many individual aspects of the expansion valve1. Individual aspects can also be claimed by themselves separate fromother aspects.

What is claimed is:
 1. An expansion valve operable by a stepper motor, the expansion valve comprising: a housing; a hollow shaft arranged in the housing; a valve base that supports the hollow shaft and closes the housing; a rotor that is drivable by a stator of the stepper motor; a center spool arranged within the hollow shaft and drivable by the rotor so that a rotation of the center spool is transferrable by a threaded connection into an axial movement of the center spool that opens or closes the expansion valve; and a spiral body that includes a thread turn and that is arranged about an enveloping surface of the hollow shaft and that is drivable by the rotor, wherein a stop body is arranged at the hollow shaft and movable in the thread turn of the spiral body, and wherein the stop body is part of a stopper structure of the center spool that predetermines an upper end position and a lower end position of the center spool.
 2. The expansion valve according to claim 1, wherein the hollow shaft includes a longitudinal groove at the enveloping surface, and wherein the stop body is configured as a sliding ring that is arranged in the thread turn of the spiral body secured against rotation by the longitudinal groove and movable in an axial direction of the expansion valve.
 3. The expansion valve according to claim 2, wherein the spool stopper structure is formed by a cooperation of the spiral body and the sliding ring.
 4. The expansion valve according to claim 2, wherein the sliding ring includes a radially inward extending protrusion that extends in the longitudinal groove and provides rotation safety for the sliding ring.
 5. The expansion valve according to claim 1, wherein the spiral body includes a first stop element that extends in an axial direction of the spiral body and a second stop element that extends in the axial direction of the spiral body.
 6. The expansion valve according to claim 5, wherein a contact of the first stop element at the stop body defines the lower end position of the center spool, and wherein a contact of the second stop element at the stop body plus a maximum torsion angle of the spiral body defines the upper end position of the center spool.
 7. The expansion valve according to claim 2, wherein the spiral body includes a first stop element that extends in an axial direction of the spiral body and a second stop element that extends in the axial direction of the spiral body, wherein the sliding ring is configured as a cylindrical coil and includes an upper end and a lower end that is arranged opposite the upper end, wherein the upper end contacts the first stop element, and wherein the lower end contacts the second stop element.
 8. The expansion valve according to claim 5, wherein the spiral body is connected by the first stop element with an adapter element so that the spiral body co-rotates with the rotor when the rotor rotates, and wherein the adapter element connects the rotor with the center spool so that the center spool co-rotates with the rotor when the rotor rotates.
 9. The expansion valve according to claim 1, wherein the spiral body is a torsion spring that is configured as a coil spring made from steel.
 10. The expansion valve according to claim 1, wherein the hollow shaft is made from a synthetic material or polyphenylene sulfide (PPS) or polyetheretherketone (PEEK) or brass or bronze.
 11. The expansion valve according to claim 1, further comprising: a sleeve element that includes a receiving portion that includes an entirety of a plunger shaped end portion of the center spool, a compression spring and a force transmission element respectively and a valve needle.
 12. The expansion valve according to claim 11, wherein the force transmission element is configured and arranged so that it contacts the center spool and transfers axial forces from the center spool through the compression spring to the sleeve element, and wherein the force transmission element is configured mushroom shaped in cross section so that torques are transferred from the center spool to the force transmission element not at all or only transferred up to a limited amount.
 13. The expansion valve according to claim 1, wherein the housing and a first side of the valve base that is oriented towards the housing define a housing cavity, wherein a hollow shaft cavity is formed within the hollow shaft, wherein a fluid inlet cavity is arranged adjacent to a second side of the valve base oriented away from the housing when the valve is installed in a valve installation cavity, wherein a first pressure balancing channel is arranged between the fluid inlet cavity and the housing cavity and configured to provide pressure balancing, wherein the first pressure balancing channel includes a first channel portion and a second channel portion, and wherein the second channel portion is formed by the longitudinal groove.
 14. The expansion valve according to claim 13, wherein a second pressure balancing channel is arranged in a portion of a maximum radial extension of the longitudinal groove and the hollow shaft cavity, and wherein the second pressure balancing channel is configured to provide pressure balancing between the hollow shaft cavity and the housing cavity. 